CN106935869B - Three-dimensional manometer cobaltosic oxide, preparation method and application - Google Patents
Three-dimensional manometer cobaltosic oxide, preparation method and application Download PDFInfo
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- CN106935869B CN106935869B CN201710204891.6A CN201710204891A CN106935869B CN 106935869 B CN106935869 B CN 106935869B CN 201710204891 A CN201710204891 A CN 201710204891A CN 106935869 B CN106935869 B CN 106935869B
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- H01M4/90—Selection of catalytic material
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Abstract
Three-dimensional manometer cobaltosic oxide, preparation method and application belong to the preparation technical field of electrochemical catalysis material.Cobalt acetate and α-aminopropionic acid are first dissolved in deionized water, dehydrated alcohol is added, is centrifuged after stirring, solid is obtained through drying, obtains Co-MOF predecessor;It by Co-MOF predecessor in tube furnace, is calcined under air atmosphere, after cooling, obtains three-dimensional manometer cobaltosic oxide, pattern is in the long and narrow graininess of olive-type, and surface aggregation has little particle, the cobalt-based complex of the uniform high catalytic performance of pattern.In OER test, it is shown that preferable performance can be applicable in electrochemical catalysis.
Description
Technical field
The invention belongs to the preparation technical fields of electrochemical catalysis material.
Background technique
Increase with the mankind to energy demand and to environmental problem concern, has caused many high efficiency, low cost, environment
It friendly energy conversion and is studied for storage.Oxygen electro-catalysis is the development core of high efficiency energy storage and conversion equipment, such as metal sky
Pneumoelectric pond and regenerative fuel cell etc..However, the development is mainly hampered by dynamics long response time: oxygen evolution reaction (OER) and oxygen
Reduction reaction (ORR): 4OH-→2H2O+4e+O2/ and its back reaction.
So far, most OER and ORR catalyst is platinum group metal mostly, such as RuO2, IrO2And Pt.However high cost
Their extensive use is limited with shortage of resources and weak stability.Therefore, many researchers are devoted to develop in recent years
Inexpensive and efficient oxygen elctro-catalyst.
Transition metal nano material and its derivative have the features such as at low cost, abundance, especially different structure and
The cobalt-based compound of dimension is to explore promising substitution OER and ORR catalyst.However, alkaline solution strong corrosive and its
The low conductivity of itself also makes cobalt-based material application development slow.By the size reduction of cobalt-based material to Nano grade, catalysis
Performance has obtained further reinforcement.This is primarily due to the distinctive property of nano material and promotes between catalyst and electrolyte
Electron-transport.
Summary of the invention
The object of the present invention is to provide a kind of three-dimensional manometer cobaltosic oxides of high electrocatalytic active.
The pattern of three-dimensional manometer cobaltosic oxide proposed by the present invention is in the long and narrow graininess of olive-type, and surface aggregation has small
Particle.
Three-dimensional manometer cobaltosic oxide has uniform olive-type pattern, particle surface and Non-smooth surface, but has spiral shell
The lamella fold of shape is revolved, i.e. aggregation little particle.
Tests prove that three-dimensional manometer cobaltosic oxide proposed by the present invention has good electrocatalysis characteristic, it is very
The new product of the OER catalyst of potential substitution precious metal material.
Second object of the present invention also proposes the preparation method of the three-dimensional manometer cobaltosic oxide with the above characteristic.
1) cobalt acetate and α-aminopropionic acid are first dissolved in deionized water, then dehydrated alcohol are added in mixed solution,
System is centrifuged after stirring, solid is obtained through drying, obtains Co-MOF predecessor;
2) it by Co-MOF predecessor in tube furnace, is calcined under air atmosphere, after cooling, obtains four oxygen of three-dimensional manometer
Change three cobalts.
The present invention by stirring and calcining two simple steps, match by the cobalt-based for preparing the uniform high catalytic performance of pattern
Close object.In OER test, it is shown that preferable performance.
The present invention is by simply stirring Co2+The aqueous solution of salt and amino acid ligand can be obtained Co-MOF predecessor.It will
Predecessor is calcined in air atmosphere and obtains three-dimensional Co3O4Nano particle.The Co obtained by this simple two-stage process3O4Nanometer
Particle not only has novel and uniform pattern, more shows excellent electrocatalysis characteristic.
The Co-MOF predecessor that step 1) technique of the present invention obtains is the solid that rose is slightly agglomerated, in oxygen atmosphere
It calcines out and sloughs the crystallization water and violent weightlessness, its quality is caused to be reduced to original 20~50%.
Further, the mixing mass ratio of α-aminopropionic acid and cobalt acetate of the present invention is 1: 1~5.The present invention uses
Two kinds of raw materials be common agents cheap and easy to get, it is higher than raw material availability using the materials, and environment is not generated dirty
Dye.
The deionized water and the mixed volume ratio of dehydrated alcohol are 1: 5~10.Complex forms full in deionized water
And solution, due to solubility and ionic effect etc., occurring complex when a large amount of ethanol solutions in the solution can be with maximum journey
The precipitation of degree, to improve the yield of material.
Co-MOF predecessor is placed in tube furnace, is promoted to in-furnace temperature with the heating rate of 0.2~5 DEG C/min
300~800 DEG C are calcined.Complex is first dehydrated and complex decomposition occurs again in slow temperature-rise period.In amino acid
The elements such as C, H, O overflow in gaseous form, form micro-nano hole in the material.These holes are material in performance test
Advantageous help is provided with the ion exchange etc. in solution.
Third purpose of the present invention is to propose the application of the above three-dimensional manometer cobaltosic oxide.
Three-dimensional cobaltosic oxide of the invention can be applicable in electrochemical catalysis.
Drop is in glass-carbon electrode or nickel foam after three-dimensional manometer cobaltosic oxide, dehydrated alcohol and Nafion solution are mixed
On the net, electrochemical sensor is made after dry.
The mixing ratio of the three-dimensional manometer cobaltosic oxide, dehydrated alcohol and Nafion solution is 40mg: 1mL: 20 μ L.
Nafion solution can increase the stability of electrode film as adhesive, but as electrically non-conductive material, excessive be added be will affect
The property of electrode film.
Detailed description of the invention
Fig. 1 is the scanning electron microscope diagram of the Co-MOF predecessor of the method for the present invention preparation.
Fig. 2 is the X-ray diffractogram of the three-dimensional manometer cobaltosic oxide of the method for the present invention preparation.
Fig. 3 is the scanning electron microscope diagram that the method for the present invention prepares three-dimensional manometer cobaltosic oxide.
Fig. 4 is that the linear scan of the three-dimensional manometer cobaltosic oxide of the method for the present invention preparation applies.
Specific embodiment
One, the preparation process and verifying of three-dimensional manometer cobaltosic oxide.
(1) after dissolution being stirred at room temperature in 100 mL deionized waters of cobalt acetate 1g and 1~5g of α-aminopropionic acid addition,
0.5~1L of dehydrated alcohol is added in solution, is centrifuged above-mentioned system after being stirred for, obtained solid spontaneously dries in air, i.e.,
Obtain Co-MOF predecessor.
Fig. 1 shows the scanning electron microscope diagram of Co-MOF predecessor.
It can be seen that there is equably olive-type pattern by the way that the resulting Co-MOF predecessor of reaction is simply stirred at room temperature,
Particle length is about 500 nm, and diameter is about 300 nm.And it is observed that the Co-MOF particle surface of olive-type simultaneously
Non-smooth surface, but there is spiral lamella fold.
It (2), will be in furnace with the heating rate of 0.2~5 DEG C/min under air atmosphere by Co-MOF predecessor in tube furnace
Temperature is promoted to 300~800 DEG C and carries out calcining 0.5~2 hour, after Temperature fall, takes out sample, as three-dimensional manometer four aoxidizes
Three cobalts.
Fig. 2 is the X-ray diffractogram of three-dimensional manometer cobaltosic oxide, the Co with standard3O4Consistent (the PDF# of crystal characteristic peak
2-1079), illustrate that this product is cobaltosic oxide material.
The scanning electron microscopy of the three-dimensional manometer cobaltosic oxide obtained after 500 DEG C of calcination temperatures is shown in Fig. 3
Mirror figure.The sample equally saves the similar olive shape of predecessor script, and is observed that sanwei nano Co3O4Nanometer
The longer and narrower olive-type of grain shape, the short grained aggregation in surface are obvious.
Two, electro-chemical test:
(1) prepared by working electrode: 40 mg of three-dimensional manometer cobaltosic oxide, 1 mL of dehydrated alcohol for taking above method to prepare
And 20 μ L of Nafion solution (perfluorinated sulfonic acid teflon-copolymers) is carried out ultrasonic mixing 10~50 minutes, is obtained suspended
Liquid.
It takes suspended drop on glass-carbon electrode with microsyringe, can carry out working in electro-chemical test after natural drying
Electrode.Or it is online in nickel foam with the suspended drop-coated of disposable dropper absorption, it can carry out working in electrochemistry after natural drying
Electrode.
(2) electrochemical property test:
This experiment is tested in KOH solution using three-electrode system, wherein being saturated sweet using platinum filament as auxiliary electrode
Mercury electrode is (SCE) reference electrode, is scanned test.
Fig. 4 shows that three-dimensional manometer cobaltosic oxide of the present invention (is swept as the electrode material line sweep test figure of electro-catalysis
Retouching speed is 5 mV s-1, reference electrode current potential is fiducial mark " zero " current potential).
Product of the present invention may occur in which current-responsive under very low voltage as seen from Figure 4, it was demonstrated that product of the present invention is one
The good electro catalytic electrode material of kind.
Claims (4)
1. a kind of pattern is in the long and narrow graininess of olive-type, surface aggregation has the preparation of short grained three-dimensional manometer cobaltosic oxide
Method, it is characterised in that include the following steps:
1) cobalt acetate and α-aminopropionic acid are first dissolved in deionized water, then dehydrated alcohol is added in mixed solution, stirred
System is centrifuged afterwards, solid is obtained through drying and obtains Co-MOF predecessor;
2) it by Co-MOF predecessor in tube furnace, is calcined under air atmosphere, after cooling, obtains the oxidation of three-dimensional manometer four three
Cobalt.
2. the preparation method of three-dimensional manometer cobaltosic oxide according to claim 1, it is characterised in that the α-aminopropionic acid
Mixing mass ratio with cobalt acetate is 1: 1~5.
3. the preparation method of three-dimensional manometer cobaltosic oxide according to claim 2, it is characterised in that the deionized water with
The mixed volume ratio of dehydrated alcohol is 1: 5~10.
4. the preparation method of three-dimensional manometer cobaltosic oxide according to claim 1, it is characterised in that by Co-MOF predecessor
It is placed in tube furnace, in-furnace temperature is promoted to 300~800 DEG C with the heating rate of 0.2~5 DEG C/min and is calcined.
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CN108448071B (en) * | 2018-01-23 | 2020-05-05 | 江苏大学 | Method for in-situ synthesis of porous nano cobaltosic oxide/carbon negative electrode material |
CN114349065A (en) * | 2020-10-13 | 2022-04-15 | 遵义师范学院 | Controllable Co3O4Simple synthesis method of nanosheet morphology and structure |
CN114349064B (en) * | 2020-10-13 | 2024-06-14 | 遵义师范学院 | Simple synthesis method capable of controlling three-dimensional structure of nano cobaltosic oxide |
CN114497828A (en) * | 2021-12-24 | 2022-05-13 | 合肥国轩高科动力能源有限公司 | Fusiform Ag/Co3O4Composite material, preparation method thereof and application thereof in lithium air battery |
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CN102583582A (en) * | 2012-03-06 | 2012-07-18 | 南京大学 | Co3O4 nanocrystal, preparation method thereof, use thereof and non-enzymatic hydrogen peroxide sensor thereof |
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